RU2485904C1 - Method of monosegmental transpedicular stabilisation of fractures of lower thoracic and lumbar vertebrae bodies - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, namely to vertebrology. Internal transpedicular screws are introduced into bodies of injured and located above it vertebrae through minimal cut. Transpedicular threaded rods of external reposition device are introduced through skin punctures into bodies of vertebrae located below the damaged vertebra. Support plates of external device are mounted on free ends of threaded rods and connected to each other with screw rods with possibility of travel relative to each other. Free end of internal transpedicular screw, introduced into the injured vertebra, is fixed to central screw rod of external reposition device via elongating bar, and correction of spine deformation and reclination of the injured vertebra are carried out. The injured and above-located vertebrae are stabilised by connection of internal transpedicular screws by means of longitudinal bars. External reposition device is dismounted and external transpedicular threaded rods are removed from bodies of vertebrae which are located below the injured vertebra.

EFFECT: reduction of trauma to tissues with complete preservation of reposition possibilities for full single-stage simultaneous spine correction and provision of reliable stabilisation of vertebral-motor segment.

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Description

The invention relates to medicine, namely to the section of traumatology and orthopedics, and can be used to treat fractures of the vertebral bodies, with the elimination of post-traumatic spinal deformity.

Known methods for treating spinal fractures using transpedicular systems (http://www.spineinfo.ru/systems/transpedfixation/). However, it is practically impossible to perform simultaneous effective correction of local kyphotic deformation at the level of the damaged vertebral segment in cases of monosegmental transpedicular fixation. For the full correction of post-traumatic deformity, it is necessary either to increase the length of the transpedicular structure [1], expanding the number of blocked segments, or to stabilize the spinal segment without performing correction of spinal deformity, which can lead to the development of secondary neurological disorders.

There is a method of external transpedicular spondylosynthesis, when the installation of transpedicular screws is performed through a puncture of the skin in the projection of the injection point, which avoids skeletalization of the posterior vertebrae, trauma to the muscular-tendon complex and, as a result, reduction of blood loss [2].

However, the fixation period by the external device is insufficient for the formation of the supporting bone block, which leads to a loss of position achieved during correction of deformation.

A known method of transpedicular osteosynthesis in the treatment of spinal injuries using a removable reposition system and the internal transpedicular system [3]. After the screws are inserted into the bodies of the injured and adjacent vertebrae and the repositional system is mounted, two more screws are inserted into the bodies of the two vertebrae of the overlying and underlying from the fixed segments, on which the repositional elements are also mounted. After the reposition is completed, internal fixation of the vertebral-motor segment is carried out by connecting the screws in the injured and adjacent vertebrae with the longitudinal rods of the transpedicular system, and the repositional system and additional screws are removed. However, to install additional screws, it is necessary to access the screw insertion points, which is accompanied by additional trauma to the soft tissues of the back; inflammatory processes are possible.

The technical task is to reduce the invasiveness of the operation, while maintaining repositional capabilities for the full correction of post-traumatic deformity and ensuring reliable stabilization of the spinal-motor segment, is solved as follows.

In the method of monosegmental transpedicular stabilization of fractures of the bodies of the lower thoracic and lumbar vertebrae using an external reposition device for correction of spinal deformity and reclamation of the damaged vertebra and the internal transpedicular system for fixing the damaged vertebral-motor segment, according to the invention, internal transpedicular screws are first inserted into the bodies through a minimum incision damaged and superior vertebrae, then through punctures of the skin in the body transpedicular threaded rods of the external reposition device are inserted from the damaged vertebra and mounted on the free ends of the threaded rods supporting plates of the external reposition device, which are connected by screw rods with the possibility of movement relative to each other, then the free end of the internal transpedicular screw inserted into the damaged vertebra through the extension rod is attached to the central screw rod of the external reposition device and is carried out to correction of spinal deformity and reclamation of the damaged vertebra, after which the damaged and overlying vertebra is stabilized by connecting the internal transpedicular screws with longitudinal rods, the external reposition device is removed and the external transpedicular threaded rods are removed from the vertebral bodies located below the damaged one.

The use of an external reposition device, the support plates of which are mounted on the free ends of the external transpedicular threaded rods and the connection of the internal transpedicular screw inserted into the damaged vertebra with the central screw rod of the external reposition device, makes it possible to carry out controlled dosage reposition of the vertebrae in all planes and to develop the compression-distraction efforts necessary values for displacement of the vertebrae to the complete elimination of all types of deformities of the spine, including the elimination of chronic wedge-shaped deformity of the vertebra and kyphotic deformation of the spine during fractures. When two vertebrae are fixed with one supporting plate and the plates can be moved relative to each other, a targeted effect on the motor vertebral segment and the damaged vertebra is achieved for reposition in any plane, in addition, it is possible to rigidly fix the spine in the achieved position. Rigid fixation by an external reposition device allows, without the change achieved during correction, the physiologically correct position of the spine, to carry out internal fixation of the damaged vertebral segment. The sequence of technological methods: the introduction of internal screws through a minimum incision, the introduction of threaded rods through a puncture of the skin and the use of a minimum number of transpedicular screws to fix one motor segment significantly reduces the invasiveness of the operation. At the same time, the authors have clinically confirmed that the monosegmental fixation of the damaged and overlying vertebra reliably stabilizes the damaged vertebral segment, while maintaining the achieved correction of the spine. In addition, early patient activation is provided, which improves the quality of life of patients.

In the Ural Institute of Traumatology and Orthopedics, the proposed method performed more than 104 operations in patients with vertebral fractures. In all cases, with minimal trauma to the soft tissues and bodies of healthy vertebrae, deformation was corrected and a complete restoration of the shape of the damaged vertebral motor segment was achieved. Patients are activated on the 3-5th day after surgery. None of the patients showed inflammatory phenomena on the part of the operated tissues; reliable stabilization of the damaged vertebral-motor segment remained until the completion of the reparative processes.

Thus, the proposed method with minimal trauma of the operation allows for metered controlled correction of existing deformations of the spine during vertebral fractures and to minimize the number of fixed vertebral-motor segments, while maintaining the stability of the damaged vertebral-motor segment.

To implement the method, standard parts from the device for external fixation of the spine and internal transpedicular system are used.

The external reposition device consists of two supporting arcuate plates with longitudinal slots in which transpedicular threaded rods are attached through expansion washers (convex and concave). The transpedicular threaded rods are mounted so that one supporting arcuate plate fixes two adjacent vertebrae (the motor segment of the spine). The supporting arcuate plates through the brackets are interconnected by a central screw rod, which consists of two parts connected by a hinge and two side screw rods. Side screw rods are connected to the brackets through expansion washers. The internal transpedicular system contains internal transpedicular screws, helical rods and blockers.

Surgery is performed under endotracheal anesthesia in the position of the patient on the abdomen. On the midline above the spinous processes of the damaged and overlying vertebrae, a minimum skin incision is made (4-6 cm) to install the internal transpedicular system. The spinous processes and arches are skeletonized to the base of the transverse processes, and the installation sites of the internal transpedicular screws are determined. They outline and form the input channel along the bow to a depth of 3 cm and, using a screwdriver, insert the internal transpedicular screws into the vertebral bodies with rotary movements. Transpedicular threaded rods are inserted into the bodies of the vertebrae downstream from the damaged vertebrae closed (through a puncture of the skin). The position of the threaded rods is controlled using an X-ray apparatus with an image intensifier tube and visually. After that, at the free ends of the transpedicular threaded rods using compensating washers, arcuate support plates are fixed so that one plate fixes two vertebrae. The plates are interconnected using brackets and screw rods (central and two side). In this case, the support of the rods on the bracket also occurs by means of expansion washers. The free end of the internal transpedicular screw inserted into the damaged vertebra is attached to the central screw rod of the external reposition device through an extension rod. Then, due to the possibility of moving the arched support plates of the external reposition device relative to each other, deformation correction (in all planes) of the damaged vertebral segment is performed. If necessary, for additional reposition and maintaining the system in tension use the compression-distraction efforts of the screw rods of the device. To do this, the middle link is mounted on the base plate using long brackets. Two lateral screw rods are fixed along the lateral edges of the support plates with shorter brackets. The position of the vertebrae is controlled using an X-ray apparatus with an image intensifier tube and visually according to the level of location of the support plates. After eliminating all types of vertebral displacements and restoring the shape of the spinal canal, all the nuts on the screw rods of the external reposition device are rigidly fixed. The internal system is mounted on the damaged vertebral segment, for which the internal transpedicular screws inserted into the vertebrae damaged and located above it are connected with screw rods in the position of maximum adaptation to the shape of the spine. The external reposition device is dismantled. The transpedicular threaded rods are removed from the external device. Layer wound closure is performed. All manipulations are carried out under image intensifier control.

Clinical example. Patient S., 36 years old, was admitted to the hospital with a diagnosis of incomplete explosive fracture of L ₁ vertebra, with a vertebral body defect. Figure 1 presents the profile x-ray of the damaged vertebra before surgical treatment.

UNIITO clinic performed transpedicular spondylosynthesis of the Th _XII- L _I segment by the proposed method with temporary installation of external transpedicular screws and deformation correction using an external reposition device.

Figure 2 presents the profile x-ray of the damaged vertebra after correction of deformation and stabilization of the vertebral segment (damaged and superior vertebra) by the internal system. On the second day after surgery, the patient is raised to her feet, on the tenth day after removal of the sutures, she was discharged from the hospital. Inflammation was not observed.

Used Books

1. Usikov V.D. Guidelines for transpedicular spinal osteosynthesis. Part 1. Damage to the spine and spinal cord. - St. Petersburg: Hippocrates, 2006 - 176 p.

2. Pat. 2115381 RF. A device and method for extra focal osteosynthesis of the spine / A.M. Lavrukov, A. B. Tomilov, D. I. Glazyrin / Publ. 07/20/98, Bull. No. 20.

3. Afaunov A.A., Usikov V.D., Afaunov A.I. Possibilities of transpedicular osteosynthesis in the treatment of injuries of the thoracic and lumbar spine / Bulletin of Traumatology and Orthopedics named after N.N. Priorov. - 2004. - No. 4. - p. 68-74.

Claims (1)

Method of monosegmental transpedicular stabilization of fractures of lower thoracic and lumbar vertebral bodies using an external reposition device for correction of spinal deformity and reclamation of a damaged vertebra and internal transpedicular system for fixing a damaged vertebral-motor segment, characterized in that the internal transpedicular screws are introduced through a minimum incision into the first the body of the damaged and superior vertebrae, then through punctures of the skin into the lower body located from the damaged vertebra, the transpedicular threaded rods of the external reposition device are inserted and the supporting plates of the external reposition device are mounted on the free ends of the threaded rods, which are interconnected by screw rods with the possibility of moving relative to each other, then the free end of the internal transpedicular screw inserted into the damaged vertebra through an extension rod is attached to the central screw rod of the external reposition device and ktsiyu spinal deformity and reclination damaged vertebra, whereupon the damaged and overlying vertebra is stabilized by connecting the inner longitudinal bars transpedicular screws, reposition the external apparatus is dismantled and removed external transpedicular screw rods downstream from the damaged vertebral bodies.

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